KR20100113583A - Telecommunications network and method for time-based network access - Google Patents

Abstract

The invention relates to a telecommunications network configured for providing access to a plurality of terminals is proposed and a method therefore. Each terminal comprises a unique identifier for accessing the telecommunications network. The telecommunications network comprises a register, an access request receiver and an access module. The register is configured for storing the unique identifier of at least one terminal in combination with at least one grant access time interval, or an equivalent thereof, during which access for the terminal is permitted. The access request receiver is configured for receiving the access request and the unique identifier for accessing the telecommunications network from the terminal. The access module is configured for denying access for the terminal if the access request is received outside the time interval, or the equivalent thereof.

Description

TELECOMMUNICATIONS NETWORK AND METHOD FOR TIME-BASED NETWORK ACCESS}

The present invention relates to the field of telecommunications. In particular, the present invention relates to a telecommunications network and a method for authorizing access to the telecommunications network.

In the past decade, the demand for data capacity in telecommunications networks has continued to increase. Telecommunication providers adapt to their networks to provide extended GSM (3G) and 3G services, such as GPRS, and continue to provide another service to meet the needs of their clients.

Telecommunications providers have attempted to influence the behavior of their clients in order to make effective use of network resources. As an example, today mobile data subscriptions are usually provided using volume based billing with volume caps as possible, and thus data sent by the client over the network. To consider the amount of. However, under the control of client and / or terminal data transmission, the use of network resources is still limited.

There is a need in the art for methods for coordinating improved telecommunication networks and the use of network resources.

There is proposed a telecommunications network configured to provide access to a plurality of terminals. Each terminal has a unique identifier (unique ID) for accessing the telecommunications network. The unique identifier is preferably associated with a subscription of the terminal, such as an identifier of a SIM (IMSI) that can be used by the terminal. The telecommunications network includes a register, an access request receiver, and an access module. The register is configured to store the unique identifier of at least one terminal with at least one grant access time interval or its equivalent time while access to the terminal is being granted. The access request receiver is configured to receive an access request and to receive or determine the unique identifier for accessing the telecommunications network from the terminal. The access module is configured to deny access to the terminal when the access request is received at a time other than the time interval or its equivalent time.

In addition, registers and serving controlling entities have been proposed for use in such networks.

In addition, a computer-implemented method of controlling access to a telecommunications network is also proposed. The telecommunications network is configured to provide access to a plurality of terminals, each having a unique identifier for accessing the telecommunications network. The telecommunications network has a register configured to store the unique identifier of at least one terminal with at least one grant access time interval or its equivalent time while access to the terminal is granted. The access request is received from the terminal for access to the telecommunications network. The access request may include a unique identifier (unique ID) or a temporary identifier (temporary ID). In another step, the grant access time interval for the terminal is verified using the unique identifier. Access to the telecommunications network for the terminal is denied if the access request is received at a time other than the time interval.

Also proposed is a computer program having a program code portion configured to execute such a method and a carrier for such a computer program.

Also proposed are terminals for use in such systems and methods.

It is to be understood that the equivalent time of the grant access time interval includes a reject access time interval that identifies the time interval during which a request for access to the telecommunications network should be denied.

The access request may be a circuit-switched access request, a packet-switched access request, or a combined request.

The step of accessing the telecommunications network is standardized, for example, in 3GGP TS 23.060 (Release 7). It should be understood that access to the telecommunications network may be denied at various access phases. Typically, the first step to request network access includes a network attach procedure with several steps. Preferably, access to the telecommunications network is denied by denying the network attach of the terminal. Rejection at this stage provides an optimized saving of resources.

Another network access step involves the establishment of a PDP context. The establishment of the PDP context may be denied. The use of network resources is already implied by the preceding network attach, but prohibiting the establishment of a PDP context saves resources by preventing effective use of telecommunication networks. Note that such operator determined barring (ODB) for access to a telecommunications network is already described in 3GGP TS 23.015, V. 7.0.0. The possibility of blocking allows the network operator to deny access to the destination for any subscriber.

By providing an option to specify one or more time intervals while access to the telecommunications network is allowed for a particular terminal or group of terminals, the control of network operator planning and the use of network resources is facilitated. Denying or blocking access during the time interval can prove to be an advantage in various situations. In particular, some machine-to-machine (M2M) applications do not require immediate data transfer. In these applications, charging one or more network resources, for example during peak load hours, can be prevented, thereby saving network resources. Such subscription may be provided, for example, at a lower subscription rate.

Typically, M2M applications rarely contain hundreds or thousands of devices that require access to a telecommunications network. One example includes the electronic reading of an electricity meter in the home of a wide range of customer bases, for example.

An embodiment of claims 2 and 13 provides a place suitable for a telecommunications network for making a combination of a terminal identifier and an associated time interval available.

The embodiment of claims 3 and 14 provides a dynamic time interval (and possibly virtual or implicit time interval) while access to the telecommunications network is granted / prohibited. These embodiments contribute to the optimal use of network resources.

Embodiments of claims 4 and 15 provide for improved use of network resources.

Embodiments of claims 5 and 16 provide for improved utilization of network resources.

The embodiment of claims 6 and 17 provides an option for notifying the terminal of the grant access time interval. Such information must be sent to the terminal in question. In addition, by allowing a single authentication can save network resources, and can save power to the terminal.

The embodiment of claims 7 and 18 ensures that a decision on whether or not to grant access to the telecommunications network is embedded in the SGSN, which reduces the low level of the telecommunications network, such as network resource consumption. do. Other solutions, such as the implementation of grant access time rules in a RADIUS server, require some network functionality, mobility management, and packet data protocol (PDP) context settings, This unnecessarily consumes network resources when it is determined that the terminal is accessed by the telecommunications network at a time other than the authorized access time interval.

Embodiments of claims 8 and 19 permit the transmission of information to a terminal. Such information may include information regarding applicable grant access time intervals. Perhaps this information may include control information for controlling the operation of the terminal. For example, the control information may control to log in the terminal during a time interval in which the network load is expected to be low. The authentication procedure is preferably performed for this terminal.

The embodiment of claims 9 and 20 provides for a higher level of authentication, for example in a GGSN, during an authorization access time interval.

In the following, embodiments of the present invention will be described in more detail. However, it should be understood that these examples should not be construed as limiting the scope of protection for the present invention.

1 shows a schematic configuration of a telecommunications network according to an embodiment of the invention.
2 illustrates HLR, SGSN and GGSN of the telecommunication network of FIG.
3A-3D show various time diagrams of a method for using the telecommunications network of FIG. 1.
4 shows a schematic configuration of a terminal for a telecommunication network of FIG.

1 shows a schematic configuration of a packet service telecommunications network 1 with a plurality of terminals A to D that can access the telecommunications network 1 for data communication.

The telecommunications network 1 has a radio access network 2 with a base transceiver station 3 and a base station controller 4. The radio access network is connected to a mobile core network having a serving controller entity 5, a register 6 and a gateway 7 providing access to another network 8.

The serving controller entity 5 may be a serving GPRS support node (SGSN) or another entity. SGSN 5 controls the connection between telecommunication network 1 and terminals A-D. It should be understood that a telecommunications network may comprise a plurality of SGSNs, each of which is typically connected to the base station controller 4 by enabling packet service to the terminal via several base stations. .

The register 6 may be a home location register (HLR) or another register (such as a home subscriber server for IMS).

The gateway 7 may be, for example, a GPRS gateway support node (GGSN) to the Internet. Other external networks include a corporate network or another network of operators. The GGSN 7 is connected to the SGSN 5 via the core network.

Access to terminals A-D to telecommunication network 1 includes a number of access steps.

The first step includes the steps during which the terminals A to D perform attachment to the telecommunications network 1. In this step, various communication steps are performed including an authentication step as exemplified in 3GGP TS 23.060 (Release 7). The authentication step performs a security function and involves the exchange of authentication triplets for GPRS or authentication quintet for UMTS.

In a subsequent step, a packet data protocol (PDP) context may be established to carry the traffic flow through the telecommunications network 1. Typically, the PDP context comprises a radio access bearer provided between the terminal A and the SGSN 5 and a switched packet data channel or tunnel provided between the SGSN 5 and the GGSN 7 have. The session between the terminal A and another party is then delivered on the established PDP context. PDP contexts may carry more than one traffic flow, but all traffic flows within one particular PDP context are handled in the same manner with respect to their transmission across the telecommunication network 1.

In operation, the terminal A transmits an access point name (APN) for a section of reference point to any external network 8 by a message requesting to activate a PDP context in the network. It may be instructed after the attach step. The SGSN 5 may, for example, send a PDP context creation request to the selected GGSN 7 according to the access point name given by the terminal A or the default GGSN known by the SGSN 5. Next, the PDP context is activated by allocating a PDP context data structure within the terminal A, which can be used as a subscriber access point, and the SGSN 5 being used by the GGSN 7. In the data structure, the IP address of the terminal A, the IMSI of the terminal A, and the tunnel ID in both the SGSN 5 and the GGSN 7 are contained. The tunnel ID is a number assigned by the GGSN 7 that identifies data related to a particular PDP context.

Various features may be controlled by the SGSN 5 during a communication session. This control is based on information associated with the subscription and may be stored within the HLR 6. This information can be retrieved from the HLR 6 to the SGSN 5 to enable control at the SGSN level.

In particular, referring to FIG. 2, the HLR 6 includes a unique identifier associated with a subscription for each terminal A-D, such as an IMSI stored in the SIM of the terminal A-D. Each terminal A to D is assigned a time interval during which access to the telecommunications network 1 can be granted.

In this example, for terminals A and B, access will be granted between 08:00 and 11:00 pm. For terminal C, access will be granted between 00:00 and 05:00 am. These time intervals are typically off-oeak intervals for nearly one year. A batch of UEs may be defined by defining a special interval of off-peak time. For terminal D, a variable time interval x-y is scheduled, depending on the network load experienced by the telecommunication network 1 or expected for the telecommunication network 1. If the network load is expected to fall below a particular threshold, or below a particular threshold, access to terminal D is granted.

Of course, the time interval may be related to a time slot while access to the telecommunications network 1 is denied, that is, during the access denial time interval. Multiple time intervals may be assigned to the terminal.

In order to control the use of resources in the telecommunications network 1, the SGSN 5 is equipped with several modules for performing the operations described in more detail below. It should be noted that one or more of these modules may be implemented as a software module running on a processor (not shown). SGSN 5 further includes memory and storage (not shown) to perform these operations in a manner generally known to the skilled person.

The SGSN 5 has an access request receiver 20 configured to receive an access request from the terminals A to D for access to the telecommunication network 1. The access request of the terminal includes the IMSI of the SIM available at this terminal.

The SGSN 5 has an access module 21 configured to deny access to the terminal to the telecommunications network when an access request is received outside the approval access time interval (or within the access denial interval) for that terminal. . This deny of access may relate to the establishment of a network attach or PDP context.

In addition, the SGSN 5 has a data retrieval module 22. This data retrieval module 22 is configured to retrieve the data from the HLR 6, in particular the applicable access grant time interval associated with the terminals A to D after the access request is received. However, it should be understood that the SGSN 5 itself may be preconfigured with respect to particular terminals, and as a result already have acknowledgment access time intervals for these terminals. This may be particularly advantageous for fixed terminals.

The SGSN 5 also has a PDP context establishment module 23 and an authenticator 23.

The SGSN 5 may also have a network load monitor 25 configured to monitor the network load of the telecommunications network 1. Network load information may also be obtained from another source, such as another SGSN or HLR of the telecommunications network 1. Network monitoring may be based on expected network load using mathematical models and historical data to obtain real time and / or reasonable load estimates.

The operation of the telecommunications network 1, and in particular the SGSN 5, will now be described with reference to FIGS. 3A to 3D.

In FIG. 3A, the access request receiver 20 of the SGSN 5 receives the access request from the terminal at 07:00 pm in step 30. In order to be able to handle this attach request, SGSN needs the IMSI of the SIM that can be used by the terminal. This attach request may include either P-TMSI assigned to the terminal by this IMSI or SGSN. P-TMSI is used to prevent the transmission of IMSI through as many wireless patches as possible for security reasons. If the P-TMSI provided by the terminal A is known in the SGSN, the SGSN can derive the IMSI. Alternatively, for the P-TMSI provided by the terminal A not known by the (new) SGSN, the IMSI is provided by either the old SGSN or the terminal itself upon request of the new SGSN. In step 31, IMSI is used by the data retrieval module 22 to retrieve the grant access time interval (08:00 to 11:00 pm) from the HLR 6 to the SGSN 5.

The grant access time interval may be communicated from the HLR 6 to the SGSN 5 in various ways.

Attach request 30 typically follows an authentication check (step 31). The grant access time interval may be sent to the SGSN 5 with an authentication triplet or quintet.

Typically, the authentication procedure of the network attach phase is followed by a location updatre procedure. First, the update position request 32 is sent from the SGSN 5 to the HLR 6. In addition, the grant access time interval may also be transmitted from the HLR 6 to the SGSN 5 by a subsequent Insert Subscriber Data (ISD) message (step 33). The network attach step is completed by an attach accept message to the terminal A (step 34).

After completing the network attach step (may have more steps than described in the previous paragraph), the PDP context is established. Terminal A requests establishment of PDP context by PDP context request 35 to activate.

Regardless of the manner of obtaining the grant access time interval, the access module of SGSN 5 determines that the access request has been received outside the grant access time interval. Thus, no PDP context is established (indicated by cross at step 36). Terminal A informs the denial in step 37.

The authentication symbol 24 of the SGSN 5 may or may not have an authenticated terminal A in the above situation. Authentication is required when the acknowledgment access time interval is sent from the HLR 6 to the SGSN 5 in response to the update location message 32. However, authentication should not be completed if the grant access time interval is obtained in SGSN 5 with an authentication triplet or quintet. If the reject message 37 to the terminal A includes information on the approval access time interval, authentication is selected.

SGSN 5 has or obtains and maintains data of failed access requests. This can be done, for example, by storing the time interval with the IMSI of the terminal A, or by temporarily displaying the terminal A with some time indication.

Another access request (step 38) at a time other than the window (08: 00-11: 00 pm) including the IMSI of the terminal A or followed by the IMSI of the terminal A may be directly rejected thereafter. (Step 39). Authentication will not be performed again.

In FIG. 3B, the network attach of the terminal A is received at 09:00 pm. Steps 40 to 45 correspond to steps 30 to 35. Since the network attach request is now within the time interval allowed for access to terminal A, access module 21 establishes a PDP context with terminal A and a PDP context with GGSN 7. In order to control the PDP context establishment module 23 of the SGSN (5). In particular, step 46 includes creating a PDP context request and step 47 includes creating a PDP context response in such a known manner. In step 48, it is known by the PDP context accept message that the terminal A activates. The terminal A may now follow another authentication procedure (step 49) using, for example, the RADIUS server of another network 8.

The network load monitoring module 25 of the SGSN 5 may monitor (part of) the network load of the telecommunications network 1 or output the expected network load. The network load may be compared with the load threshold to assess the presence of low network load conditions at particular times or time intervals.

In Fig. 3C, steps 50 to 53 correspond to steps 30 to 33 in Fig. 3A. Authentication of terminal D is performed in step 54, and terminal D informs the time interval x-y while a low network load is expected. This information includes control information for controlling the terminal D to access the telecommunications network 1 again (step 55) in such a low network load time interval. The PDP context can be set up immediately and access to the RADIUS server is allowed.

As described above, the denial of access to the telecommunications network 1 is preferably performed during the network attach. 3D shows the network attach message of the terminal A including the IMSI in step 60. Thereafter, an authentication procedure is performed while the acknowledgment access time interval is being received at the SGSN 5 (step 61). The grant access time interval and IMSI are stored at SGSN 5. Alternatively, the grant access time interval is obtained in the location update procedure (steps 62 and 63). The network attach is rejected in step 64.

As described above, the SGSN 5 itself may have preconfigured information regarding the grant access time interval for the terminal A. FIG. Alternatively, SGSN uses authentication symbol 24 to authenticate terminal A in step 61 and to provide terminal A with information about the authorization access time interval.

4 shows a schematic configuration of the terminal A. As shown in FIG. The terminal A is provided with a transceiver module 70 for communicating with the telecommunications network 1. Terminal A further has an access request module 71. The access request module is configured to receive information regarding an acknowledgment access time interval from the telecommunications network 1 via the transceiver module 70 and to transmit an access request to the telecommunication network only at a predetermined time within the acknowledgment access time interval. .

It should be noted that the telecommunication networks and systems described above are particularly suitable for saving resources. There may be other approaches that affect the access behavior of the terminal, but these are considered to throw away additional resources.

As an example, the network provider allows access to the network at all times but is filled at (very) high rates for data sent outside of the off-peak time. This provides no incentive for the user to tear down the connection to the network (ie, the PDP context). This only provides incentives to avoid sending data during expensive peak times. However, active PDP contexts still consume many resources in mobile wireless and core networks as well as require IP addresses. This also requires a terminal mounted in the network which means that all sorts of mobility management features must be in place. Moreover, this solution requires a more complex billing system that allows filling at higher speeds at some time.

Another example is the rule at the RADIUS server, which includes blocking access to the terminal during peak times. However, network resources will already be consumed before access is blocked by the RADIUS server. The terminal has already allowed the SGSN to be installed in the network, which means that the information from the HLR has been retrieved, and performs the mobility management function. In addition, the terminal allowed to establish a PDP context. If the RADIUS server rejects the request for access to the external data network, the GGSN will not accept the PDP context and the tunnel will be taken down. However, mounting to the network will continue unless additional measures are taken.

Claims (23)

A telecommunications network for providing access to a plurality of terminals, each having a unique identifier (unique ID) for accessing a telecommunications network,
A register configured to store the unique identifier of at least one terminal with at least one grant access time interval or its equivalent time while access to the terminal is granted;
An access request receiver configured to receive an access request and to receive or determine from the terminal the unique identifier for accessing the telecommunications network;
And an access module configured to deny access to the terminal when the access request is received at a time other than the time interval or its equivalent time.
2. The telecommunications network of claim 1, wherein the telecommunications network comprises a cellular network and the register is a Home Location Register (HLR) or a Home Subscriber Server (HSS) of a cellular telecommunications network. Telecommunications network.
3. The telecommunications network of claim 1 or 2, wherein the telecommunications network includes a network load monitor configured to monitor a network load of the telecommunications network, the telecommunications network dependent upon the network load. Telecommunications network, adapted to adapt to a time interval or equivalent time thereof.
The telecommunications network of any one of the preceding claims wherein the access module is configured to reject network attach to the telecommunications network.
The telecommunications network of any preceding claim, wherein the network module is further configured to deny access without authentication of the terminal.
The apparatus of claim 1, further comprising an authentication module configured to authenticate the terminal in response to receiving the access request,
The access module is further configured to reject a network attach upon receipt of another access request from the terminal.
The telecommunications network of claim 1, wherein the telecommunications network comprises a serving controller entity having the access request receiver and the access module,
The serving controller entity further comprises a data retrieval module configured to retrieve the time interval or its equivalent time from the register in response to receiving the access request, wherein the access module includes a network attachment to the telecommunications network. The device is configured to refuse to establish a packet data protocol context with the terminal if the device rejects an access request or the access request is received within the searched time interval.
The network of claim 1, wherein the network comprises a serving controller entity configured to transmit access denial information to the terminal in response to the access module denying access to the telecommunications network. Telecommunications network, characterized in that.
The telecommunications network of any preceding claim, wherein the network further comprises a gateway to another network, and wherein the access node is configured to allow another authentication of the terminal.
A register for use in a telecommunications network according to any one of the preceding claims.
Serving controller entity for use in a telecommunications network according to any of the preceding claims.
Each configured to permit access to a plurality of terminals having a unique identifier for accessing a telecommunications network, and configured to store the unique identifier of at least one terminal with at least one grant access time interval or equivalent time thereof. A computer-implemented method for controlling access to a telecommunications network having registers, the computer-implemented method comprising:
Receiving an access request and the unique identifier for accessing the telecommunications network from the terminal;
Accessing the time interval or its equivalent time using the unique identifier,
And denying access to the telecommunications network to the terminal when the access request is received at a time other than the time interval or its equivalent time.
13. The computer implemented method of claim 12 wherein the telecommunications network comprises a cellular network and the register is an HLR or an HSS of a cellular telecommunications network.
The method of claim 12 or 13, further comprising: monitoring network load of the telecommunications network;
And adapting to the time interval or its equivalent time depending on the network load.
15. The method according to any one of claims 12 to 14, wherein the step of denying access to the telecommunications network for the terminal when the access request is received at a time other than the time interval or its equivalent time, comprises: And rejecting a network attach to the telecommunications network.
16. The computer-implemented method of any one of claims 12 to 15, further comprising the step of denying access of the terminal in the telecommunications network without authentication of the terminal.
17. The method of any one of claims 12 to 16, further comprising: authenticating the terminal in the telecommunications network in response to receiving the access request;
And denying a network attach to the terminal in response to receiving another access request from the terminal.
18. The method of any one of claims 12 to 17, further comprising: receiving the access request from the serving controller entity to the telecommunications network;
Retrieving the time interval or its equivalent time from the register to the serving controller entity in response to receiving the access request;
Rejecting a network attach to the telecommunications network or refusing to establish a packet data protocol context for the terminal if the access request is received within the retrieved time interval. .
19. The computer implemented method of any one of claims 12 to 18, further comprising the step of transmitting access denial information to the terminal in addition to denying access to the telecommunications network.
19. The computer-implemented method of any one of claims 12 to 18, further comprising authenticating the terminal for access to another network during the access grant time interval.
A computer program product for controlling access to a telecommunications network, the computer program product comprising a portion of software code configured to execute the method of claim 12 when executed in a telecommunications network.
A carrier comprising the computer program product according to claim 21.
A terminal for use in a telecommunications network according to claim 1,
A message receiver configured to receive a message from the telecommunications network,
The message has information regarding an approval access time interval or its equivalent time,
And the terminal further comprises an access request module configured to transmit the access request to the telecommunications network according to the access authorization time interval.

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